CN204425185U - Power supply selection circuit - Google Patents

Abstract

A power selection circuit comprises a first adjusting circuit, at least a second adjusting circuit and a control circuit. The first regulating circuit is provided with a first control end, a first input end and a first output end, wherein the first control end is connected with a first voltage, the first input end is connected with an input voltage, and the first output end can generate a third voltage; the second regulating circuit is provided with a second control end, a second input end, a second output end and a regulating switch element, wherein the second control end is connected with the first voltage, the second input end is connected with the second voltage, and the second output end is connected with the first output end; the control circuit is coupled to the first regulating circuit and the second regulating circuit and controls the on-off of the regulating switch element according to the first voltage, the second voltage and the third voltage. Therefore, each regulating circuit can be ensured to be in a cut-off state before the required input voltage reaches the starting voltage value, so that the abnormal operation of the regulating circuit is avoided.

Description

Power selection circuit

Technical field

The utility model relates to a kind of power control circuit, and relates to a kind of power selection circuit of linear voltage regulator especially.

Background technology

Current electronic equipment (as: desktop computer, notebook computer, measuring equipment) is to the demand sustainable growth of various stabilized voltage power supply, how through the power selection circuit comprising some regulating circuits for electronic equipment provides burning voltage to become an important topic, and regulating circuit is because regulatory requirements, low-voltage-drop linear voltage regulator (low dropout regulator) is widely used.The power selection circuit of existing many application low-voltage-drop linear voltage regulator compositions, when apply multiple low-voltage-drop linear voltage regulator through contact potential series with the various voltage providing different elements in electronic equipment and need separately time, the easy adverse current of electric charge of the output voltage generation of power selection circuit is in the low-voltage-drop linear voltage regulator do not started, cause abnormal operation, upset power selection circuit normally provides the input voltage needed for each regulating circuit according to contact potential series, and output voltage so also can be caused unstable.

Existing power selection circuit cannot use the standard of the ceiling voltage position in each low-voltage-drop linear voltage regulator whether to start to control this low-voltage-drop linear voltage regulator, causes output voltage unstable.

Utility model content

An object of the present utility model is providing a kind of power control circuit, to solve the problem of prior art.

In an embodiment, power selection circuit provided by the utility model comprises the first regulating circuit, at least one second regulating circuit and control circuit.First regulating circuit has the first control end, first input end and the first output, and wherein the first control end connects the first voltage, and first input end connects input voltage, and the first output can produce tertiary voltage; Second regulating circuit has the second control end, the second input, the second output and by-pass cock element, and wherein the second control end connects the first voltage, and the second input connects the second voltage, and the second output connects this first output; Control circuit is coupled to the first regulating circuit and the second regulating circuit, and according to the first voltage, the second voltage and tertiary voltage with the keying of regulating and controlling switch element.

In an embodiment, the first regulating circuit is low-voltage-drop linear voltage regulator (low dropout regulator), and the second regulating circuit is another low-voltage-drop linear voltage regulator.

In an embodiment, second regulating circuit has controller, N-type metal-oxide semiconductor (MOS) and at least one P-type mos, its middle controller connects the grid of the first voltage and N-type metal-oxide semiconductor (MOS), and the source electrode of P-type mos connects the second voltage.

In an embodiment, by-pass cock element is P-type mos (P-type Metal Oxide Semiconductor, PMOS), the wherein grid connection control circuit of by-pass cock element, the source electrode of by-pass cock element connects the second input, and the drain electrode of by-pass cock element connects the second output.

In an embodiment, control circuit is that multiple equivalent diode element (equivalent diode) in parallel is to accept the first voltage, the second voltage and tertiary voltage, the anode of these equivalent diode elements is electrically connected the first voltage, the second voltage and tertiary voltage respectively, to receive the maximum in the middle of the first voltage, the second voltage and tertiary voltage, and the electrical connection control switch element of the negative electrode of these equivalent diode elements.

In an embodiment, these equivalent diode elements are multiple N-type metal-oxide semiconductor (MOS) (N-type Metal Oxide Semiconductor, NMOS), wherein the grid of these N-type metal-oxide semiconductor (MOS)s is connected with source electrode using the anode as these equivalent diode elements, and the drain electrode of these N-type metal-oxide semiconductor (MOS)s is as the negative electrode of these equivalent diode elements.

In an embodiment, control switch element is another P-type mos, and when the grounded-grid of control switch element, control switch element can be opened, and when the grid of control switch element is connected with source electrode, control switch element can be closed.

In an embodiment, power selection circuit also comprises comparing element, is coupled to control circuit, in order to when the second voltage reaches starting resistor value, produces triggering signal and is connected with source electrode, with closing control switch element to make the grid of control switch element.

In sum, the technical solution of the utility model compared with prior art has obvious advantage and beneficial effect.By technique scheme, can reach suitable technological progress, and have the extensive value in industry, with regulating and controlling circuit start whether its advantage uses the ceiling voltage position in regulating circuit accurate.

Accompanying drawing explanation

For above and other object of the present utility model, feature, advantage and embodiment can be become apparent, appended the description of the drawings is as follows:

Fig. 1 is the schematic diagram of a kind of power selection circuit according to the utility model one embodiment;

Fig. 2 is the schematic diagram of the contact potential series received according to the control circuit of the utility model one embodiment;

Fig. 3 is the schematic diagram of the control circuit illustrated according to the utility model Fig. 1;

Fig. 4 is the circuit diagram of the control circuit illustrated according to the utility model Fig. 3; And

Fig. 5 is the schematic diagram of a kind of power selection circuit according to another embodiment of the utility model.

Embodiment

In order to make of the present utility model describe more detailed and complete, below will clearly demonstrate spirit of the present utility model with accompanying drawing and detailed description, have in any art and usually know that the knowledgeable is after understanding preferred embodiment of the present utility model, when can by the technology of the utility model institute teaching, be changed and modify, it does not depart from spirit of the present utility model and scope.On the other hand, well-known element and step are not described in embodiment, to avoid causing unnecessary restriction to the utility model.

Power selection circuit shown in the utility model is the voltage for the voltage transitions of input being become relative low voltage value, and convert multiple different magnitude of voltage to, the input voltage needed for the multiple regulating circuits in power selection circuit is sequentially provided by contact potential series (voltage sequence); Due to power selection circuit the voltage transitions of input become the voltage of relative low voltage value and converts multiple different magnitude of voltage to time, multiple magnitude of voltage can produce in different time according to contact potential series, power selection circuit shown in the utility model can guarantee that each regulating circuit is before input voltage required separately reaches starting resistor value, be in cut-off state, to avoid regulating circuit abnormal operation, cause power selection circuit normally cannot provide the input voltage needed for each regulating circuit according to contact potential series, also cause output voltage unstable.Fig. 1 is the schematic diagram of a kind of power selection circuit according to the utility model one embodiment.As shown in Figure 1, in an embodiment, power selection circuit comprises the first regulating circuit 110, second regulating circuit 120 and control circuit 130.First regulating circuit 110 has the first control end 111, first input end 112 and the first output 113.First regulating circuit 110 need have operating voltage (operation voltage) to supply the first regulating circuit 110 is in can operating state, in the present embodiment, the first control end 111 connects the first voltage 141 to obtain the operating voltage of the first regulating circuit 110.In an embodiment, first regulating circuit 110 can be low-voltage-drop linear voltage regulator (low dropout regulator), low-voltage-drop linear voltage regulator can be made up of operational amplifier (operational amplifier) 114 and P-type mos (P-type Metal Oxide Semiconductor, PMOS) 115; Needing first to obtain the first voltage 141 by first input end 111 makes the operational amplifier 114 in the first regulating circuit 110 obtain required operating voltage (as: 3V), operational amplifier 114 again according to its non-inverting input (non-inverting input) and pressure reduction between reverse input end (inverting input), export after the pressure reduction between non-inverting input and reverse input end being amplified with the differential gain of operational amplifier (differential gain); Wherein, the reverse input end of operational amplifier 114 can connect a fixing reference voltage (as: 2V), and the dividing potential drop supply of the tertiary voltage 143 that the non-inverting input voltage of operational amplifier 114 exports by the first output 113 of the first regulating circuit 110, its dividing potential drop based on resistance 191 and resistance 192 to determine.First voltage 141 as above, its embodiment can be the system voltage source of circuit.

The output of operational amplifier 114 can be connected to the grid of P-type mos 115, the operating area of P-type mos 115 is the grids according to P-type mos 115, the voltage of source electrode and drain electrode determined, when the first regulating circuit 110 accepts input voltage 144 (as: 20V), input voltage 144 can by first input end 112 to connect the source electrode of P-type mos 115, now P-type mos 115 can operate in linear zone (linear region), first regulating circuit 110 exports tertiary voltage 143 by the drain electrode of P-type mos 115.Input voltage 144 as above, its embodiment can be the system voltage source of circuit.

Second regulating circuit 120 can be another low-voltage-drop linear voltage regulator, and in an embodiment, the second regulating circuit 120 has the second control end 121, second input 122, second output 123 and by-pass cock element 125; Second regulating circuit 120 is parallel to the first regulating circuit 110, and namely the second control end 121 also can connect the first voltage 141, originates, and be connected with the second output 123 by the first output 113 using the first voltage 141 as the operating voltage of the second regulating circuit 120.The reverse input end of the operational amplifier 124 in the second regulating circuit 120 can connect a fixing reference voltage (as: 2V), and the dividing potential drop supply of the tertiary voltage 143 that the non-inverting input voltage of operational amplifier 124 exports by the first regulating circuit 110, its dividing potential drop is based on resistance 191 and resistance 192 to determine, the output of operational amplifier 124 is connected to by-pass cock element 125.

In an embodiment, by-pass cock element 125 can be P-type mos.The operating area of P-type mos is grid according to P-type mos, the voltage of source electrode and drain electrode determined; When the second voltage 142 not yet inputs to the second regulating circuit 120, if the output voltage of operational amplifier 124 is less than the tertiary voltage 143 that the first regulating circuit 110 exports, then P-type mos can operate in saturation region (saturation region), now, tertiary voltage 143 can make electric charge via drain electrode adverse current to the second regulating circuit 120 of P-type mos, and control circuit 130 can avoid the electric charge of tertiary voltage 143 via drain electrode adverse current to the second regulating circuit 120 of P-type mos.When drain electrode adverse current to the second regulating circuit 120 via P-type mos of the electric charge of tertiary voltage 143, the second regulating circuit 120 can be caused normally cannot to obtain according to contact potential series the second voltage 142 reaching starting resistor value from the second input 122.Second voltage 142 as above, its embodiment can be the system voltage source of circuit.

For guaranteeing that P-type mos in the second regulating circuit 120 is during the second voltage 142 inputs, the electric charge of tertiary voltage 143 via drain electrode adverse current to the second regulating circuit 120 of P-type mos, can not affect the generation of the second voltage 142 that the second input 122 receives; Before the second voltage 142 is not yet increased to the starting resistor value needed for the second regulating circuit 120, by control circuit 130 to control the grid voltage of P-type mos, the grid voltage of P-type mos is made to be in high potential, now P-type mos can operate in cut-off region (cut-off region), the electric charge of tertiary voltage 143 just via drain electrode adverse current to the second input 122 of P-type mos 122, can not affect the generation of the second voltage 142.

Control circuit 130 is coupled to the first regulating circuit 110 and the second regulating circuit 120, wherein control circuit 130 is according to the magnitude of voltage of the first voltage 141, second voltage 142 and tertiary voltage 143, select the maximum in the middle of the first voltage 141, second voltage 142 and tertiary voltage 143, the grid inputing to P-type mos is provided, makes the grid voltage of P-type mos be in high potential.Fig. 2 is the schematic diagram of the contact potential series received according to the control circuit 130 of the utility model one embodiment.As shown in Figure 2, carry and give in the voltage source of power selection circuit altogether, due to the operating voltage that the first voltage 141 is the first regulating circuit 110 and the second regulating circuit 120, can produce at first in contact potential series, after the first regulating circuit 110 starts, tertiary voltage 142 can with generation, and be supplied to the non-inverting input of operational amplifier 114 with its dividing potential drop; After the first regulating circuit 110 starts generation tertiary voltage 142, power selection circuit produces the second voltage 142 according to contact potential series, and the second voltage 142 can increase until reach required starting resistor value gradually.

As mentioned above, control circuit 130 controls the grid being arranged in the P-type mos of the second regulating circuit 120, when grid voltage due to P-type mos is in high potential, P-type mos can operate in cut-off region, effect is if same switch is to control P-type mos, therefore P-type mos can be used as the by-pass cock element 125 of the second regulating circuit 120, wherein the grid of by-pass cock element 125 is coupled to control circuit 130, the source electrode of by-pass cock element 125 is second inputs 122, connect the second voltage 142, the drain electrode of by-pass cock element 125 is second outputs 123, be connected to the tertiary voltage 143 that the first regulating circuit 110 exports.

Control circuit 130 according to the magnitude of voltage of the first voltage 141, second voltage 142 and tertiary voltage 143 with the keying of regulating and controlling switch element 125.When the second voltage 142 reaches starting resistor value (as: 5V), control circuit 130 can open by-pass cock element 125 to start the second regulating circuit 120, the second voltage 142 is made to input to the second regulating circuit 120, and control circuit 130 can cut out the first regulating circuit 110, make the second regulating circuit 120 receive the second voltage 142 reaching starting resistor value, produce tertiary voltage 143 with the function of first regulating circuit 110 that continues.

The input voltage 144 of the first regulating circuit 110 is high relative to the second voltage 142 of the input of the second regulating circuit 120, such as: input voltage 144 is 20V, the starting resistor value of the second voltage 142 is 5V, when the first regulating circuit 110 starts, an electric current I (not shown) can be produced, after the second regulating circuit 120 starts, control circuit 130 can cut out the first regulating circuit 110, with regard to the consumed power of power selection circuit is considered, when electric current I is identical, the power that second regulating circuit 120 consumes when starting is low when can start compared with the first regulating circuit 110, moreover, in the utilization of general voltage sequential, input voltage 144 can first produce to start the first regulating circuit 110, second voltage 142 can reach starting resistor value more gradually to start the second regulating circuit 120.

Power selection circuit also comprises comparing element 150, and in implementation, comparing element 150 can be operational amplifier or comparator.When the second voltage 142 reaches starting resistor value, input voltage 144 and the second voltage 142 may exist simultaneously, control circuit 130 detects the second voltage 142 through comparing element 150 and reaches starting resistor value, produce triggering signal to start the second regulating circuit 120, now, the first regulating circuit 110 and the second regulating circuit 120 have all started and have operated; Control circuit 130 through comparing element 150 detect the second voltage 142 reach starting resistor value and for stationary value time, produce triggering signal to close the first regulating circuit 110.Should be appreciated that, above lifted example is also not used to limit the utility model, and those who are familiar with this art work as depending on needing at that time, the embodiment of elasticity selection and comparison element 150.

Because control circuit 130 is according to the magnitude of voltage of the first voltage 141, second voltage 142 and tertiary voltage 143, as mentioned above, the grid voltage of regulating and controlling switch element 125 is in high potential, when not reaching starting resistor value to make the second voltage 142 of the second regulating circuit 120, by-pass cock element 125 is closed, avoids electric charge adverse current to the second regulating circuit 120 of tertiary voltage 143.Fig. 3 is the schematic diagram of the control circuit illustrated according to the utility model Fig. 1.As shown in Figure 3, in an embodiment, control circuit 130 is multiple equivalent diode elements (equivalent diode) 161 in parallel, 162, 163 to accept the first voltage 141, second voltage 142 and tertiary voltage 143, these equivalent diode elements 161, 162, the anode of 163 is electrically connected the first voltage 141 respectively, second voltage 142 and tertiary voltage 143, to receive the first voltage 141, the maximum in the middle of second voltage 142 and tertiary voltage 143, and these equivalent diode elements 161, 162, the control switch element 164 of the electrical connection control circuit 130 of negative electrode of 163, when the switch open of control switch element 164, control circuit 130 through control switch element 164 to export the first voltage 141, the maximum in the middle of second voltage 142 and tertiary voltage 143 is to the grid of by-pass cock element 125.

In above-described embodiment, in implementation, equivalent diode element 161,162,163 can be and is respectively multiple N-type metal-oxide semiconductor (MOS) (N-type Metal Oxide Semiconductor, NMOS).Fig. 4 is the circuit diagram of the control circuit illustrated according to the utility model Fig. 3.As shown in Figure 4, equivalent diode element 161,162,163 (being illustrated in Fig. 3) can specifically be implemented with N-type metal-oxide semiconductor (MOS) 171,172,173 respectively, wherein the grid of these N-type metal-oxide semiconductor (MOS)s 171,172,173 is connected with source electrode using the anode as these equivalent diode elements 161,162,163, and the drain electrode of these N-type metal-oxide semiconductor (MOS)s 171,172,173 is as the negative electrode of these equivalent diode elements 161,162,163.Should be appreciated that, above lifted example is also not used to limit the utility model, and those who are familiar with this art work as depending on needing at that time, and elasticity selects the embodiment of equivalent diode element 161,162,163.

In above-described embodiment, the control switch element 164 shown as depicted in fig. 3, in implementation, can as Fig. 4 the control switch element 174 that illustrates be another P-type mos, when the grounded-grid of control switch element 174, control switch element 174 can be opened, control circuit 130 through control switch element 174 to export the grid of the maximum in the middle of the first voltage 141, second voltage 142 and tertiary voltage 143 to by-pass cock element 125.When the grid of control switch element 174 is connected with source electrode, control switch element 174 can be closed, and control circuit 130 does not just reoffer the grid of voltage to by-pass cock element 125.And the grid of control switch element 174 is through comparing element 150 to determine its ground connection or to be connected with the source electrode of control switch element 174.When the second voltage 142 does not reach starting resistor value, the grid of control switch element 174 is ground connection, when the second voltage 142 reaches starting resistor value, input voltage 144 (being illustrated in Fig. 1) and the second voltage 142 may exist simultaneously, control circuit 130 through comparing element 150 detect the second voltage 142 reach starting resistor value and for stationary value time, produce triggering signal to be connected with source electrode to make the grid of control switch element 174, with closing control switch element 174, control circuit 130 can cut out the first regulating circuit 110, do not provide voltage to the grid of by-pass cock element 125, now power selection circuit is operated by the second regulating circuit 120, export tertiary voltage 143.

As shown in Figure 2, Figure 4 shows, in an embodiment, the first voltage 141 is only had to produce in period 210, when only having the first voltage 141 to produce, control circuit 130 receives the first voltage 141, exports the grid of by-pass cock element 125 through control switch element 174 to, and now the grid of by-pass cock element 125 is maximum potential for the source electrode of by-pass cock element 125 and drain electrode, therefore by-pass cock element 125 operates in cut-off region, to close the second regulating circuit 120.

In the period 220, the first voltage 141 is only had to produce at the beginning, tertiary voltage 143 starts to produce afterwards, first voltage 141 exists with tertiary voltage 143 simultaneously, now control circuit 130 still continuous reception first voltage 141, through control switch element 174 with lasting closedown second regulating circuit 120.In the period 230, the first voltage 141 exists with tertiary voltage 143 simultaneously, and the second voltage 142 starts to produce afterwards, and the first voltage 141, second voltage 142 and tertiary voltage 143 exist simultaneously; When tertiary voltage 143 is greater than the first voltage 141 and the second voltage 142, control circuit 130 receives tertiary voltage 143, exports the grid of by-pass cock element 125 to lasting closedown second regulating circuit 120 through control switch element 174.

In the period 240, the first voltage 141, second voltage 142 and tertiary voltage 143 exist simultaneously, and the second voltage 142 is greater than the first voltage 141 and tertiary voltage 143, but do not reach starting resistor value; When the second voltage 142 is greater than the first voltage 141 and tertiary voltage 143 and does not reach starting resistor value, control circuit 130 receives the second voltage 142, exports the grid of by-pass cock element 125 to lasting closedown second regulating circuit 120 through control switch element 174.

In the period 250, the first voltage 141, second voltage 142 and tertiary voltage 143 exist simultaneously, and the second voltage 142 is greater than the first voltage 141 and tertiary voltage 143 and reaches starting resistor value; When the second voltage 142 is greater than the first voltage 141 and tertiary voltage 143 and reaches starting resistor value, control circuit 130 receives starting resistor value, exports the grid of by-pass cock element 125 through control switch element 174 to.As mentioned above, control circuit 130 detects the second voltage 142 through comparing element 150 and reaches starting resistor value, comparing element 150 produces triggering signal and is connected with source electrode to make the grid of control switch element 174, with closing control switch element 174, start the second regulating circuit 120 whereby, now, the first regulating circuit 110 and the second regulating circuit 120 have all started and have operated; Control circuit 130 through comparing element 150 detect the second voltage 142 reach starting resistor value and for stationary value time, produce triggering signal to close the first regulating circuit 110, make the second regulating circuit 120 receive the second voltage 142 reaching starting resistor value, produce tertiary voltage 143 with the function of first regulating circuit 110 that continues.

As shown in Figure 1, the first regulating circuit 110 and the second regulating circuit 120 can be low-voltage-drop linear voltage regulator, and the circuit of low-voltage-drop linear voltage regulator has multiple implementation.Fig. 5 is the schematic diagram of a kind of power selection circuit according to another embodiment of the utility model.As shown in Figure 5, controller 521, N-type metal-oxide semiconductor (MOS) 522, P-type mos 523 and P-type mos 524 is comprised in the second regulating circuit 520; Controller 521 connects the first voltage 141 and obtains power supply needed for the second regulating circuit 520, controller 521 connects the grid of N-type metal-oxide semiconductor (MOS) 522, make the output voltage of controller 521 via N-type metal-oxide semiconductor (MOS) 522 to adjust the electric current flowing into P-type mos 523, second voltage 142 of input is transformed into the output voltage of regulating circuit 520 by the current mirror (current mirror) formed via P-type mos 523 and P-type mos 524 again, i.e. tertiary voltage 143.The voltage sequential of the first voltage 141, second voltage 142 and tertiary voltage 143, illustrated as Fig. 2.Tertiary voltage 143 first exported by the first regulating circuit 110, will likely produce ahead of time than the second voltage 142.Control circuit 530 shown in Fig. 5 comprises switch element 531 and ON-OFF control circuit 532, the effect control circuit 130 as shown in Figure 1 of this control circuit 530, be to guarantee that P-type mos 523 and P-type mos 524 can really end during wait second voltage 142 is set up, as for how passing through control circuit 530 to control the keying of P-type mos 523 and P-type mos 524, because above embodiment specifically discloses, therefore it is no longer repeated.

In another embodiment, it is multiple with the second regulating circuit 120 framework same adjustment circuit in parallel with other that power selection circuit can be the first regulating circuit 110, second regulating circuit 120, and power selection circuit provides the input voltage needed for each regulating circuit according to contact potential series; Should be appreciated that, those who are familiar with this art, when depending on needing at that time, adjust the embodiment of these regulating circuits through the power selection circuit elasticity disclosed by the utility model.

Although the utility model discloses as above with execution mode; so itself and to be not used to limit the utility model bright; anyly be familiar with this those skilled in the art; not departing from spirit and scope of the present utility model; when being used for a variety of modifications and variations, the scope that therefore protection range of the present utility model ought define depending on appending claims is as the criterion.

Claims (8)

1. a power selection circuit, is characterized in that, comprises:

One first regulating circuit, has one first control end, a first input end and one first output, and wherein this first control end connects one first voltage, and this first input end connects input voltage, and this first output can produce a tertiary voltage;

At least one second regulating circuit, there is one second control end, one second input, one second output and a by-pass cock element, wherein this second control end connects one first voltage, and this second input connects one second voltage, and this second output connects this first output; And

One control circuit, is coupled to this first regulating circuit and this second regulating circuit, and according to this first voltage, this second voltage and this tertiary voltage to control the keying of this by-pass cock element.

2. power selection circuit according to claim 1, is characterized in that, this first regulating circuit is a low-voltage-drop linear voltage regulator, and this second regulating circuit is another low-voltage-drop linear voltage regulator.

3. power selection circuit according to claim 2, it is characterized in that, this second regulating circuit has a controller, a N-type metal-oxide semiconductor (MOS) and at least one P-type mos, wherein this controller connects the grid of this first voltage and this N-type metal-oxide semiconductor (MOS), and the source electrode of this P-type mos connects this second voltage.

4. power selection circuit according to claim 1, it is characterized in that, this by-pass cock element is a P-type mos, wherein the grid of this by-pass cock element connects this control circuit, the source electrode of this by-pass cock element connects this second input, and the drain electrode of this by-pass cock element connects this second output.

5. power selection circuit according to claim 1, it is characterized in that, this control circuit has a control switch element, and this control circuit is that multiple equivalent diode element in parallel is to accept this first voltage, this second voltage and this tertiary voltage, the anode of described equivalent diode element is electrically connected this first voltage, this second voltage and this tertiary voltage respectively, to receive the maximum in the middle of this first voltage, this second voltage and this tertiary voltage, and the negative electrode of described equivalent diode element is electrically connected this control switch element.

6. power selection circuit according to claim 5, it is characterized in that, described equivalent diode element is multiple N-type metal-oxide semiconductor (MOS)s, the grid of wherein said N-type metal-oxide semiconductor (MOS) is connected with source electrode using the anode as described equivalent diode element, and the drain electrode of described N-type metal-oxide semiconductor (MOS) is as the negative electrode of described equivalent diode element.

7. power selection circuit according to claim 5, it is characterized in that, this control switch element is another P-type mos, when the grounded-grid of this control switch element, this control switch element can be opened, when the grid of this control switch element is connected with source electrode, this control switch element can be closed.

8. power selection circuit according to claim 7, is characterized in that, also comprises:

One comparing element, is coupled to this control circuit, in order to when this second voltage reaches a starting resistor value, produces a triggering signal and is connected with source electrode to make the grid of this control switch element, to close this control switch element.